Dongle for outputting an ultrasound image acquired at an ultrasound machine controlled by a multi-use display device, and related methods

ABSTRACT

The present embodiments relate generally to methods for providing viewing access to an ultrasound image feed generated at an ultrasound imaging machine. A multi-use display device may form a first link-layer connection with the ultrasound image machine for transmitting commands that control imaging parameters of the ultrasound image feed. The multi-use display device may then: determine link-layer connection parameters that allow the ultrasound imaging machine to form a second link-layer connection with a receiving device (the receiving device having no link-layer connection with the ultrasound imaging machine), and provide the connection parameters to the receiving device. The ultrasound imaging machine forms a second link-layer connection with the receiving device, based the connection parameters. The second link-layer connection is then used for receiving, at the receiving device, the ultrasound image feed controlled by the multi-use display device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/872,312, filed May 11, 2020, which is a continuation of U.S. patentapplication Ser. No. 15/936,948, filed Mar. 27, 2018. U.S. patentapplication Ser. No. 15/936,948 issued to patent as U.S. Pat. No.10,646,205. The entire contents of U.S. patent application Ser. No.16/872,312 and U.S. patent application Ser. No. 15/936,948 are herebyincorporated by reference.

FIELD

The present disclosure relates generally to ultrasound imaging, and inparticular, systems and methods of establishing a secondary connectionat an ultrasound imaging machine, for providing access to an ultrasoundimage feed.

BACKGROUND

Ultrasound imaging systems are a powerful tool for performing real-time,non-invasive imaging procedures in a wide range of medical applications.These systems typically include a display for showing an ultrasoundimage feed to an operator. In certain situations, it may be desirable toprovide viewing access of the ultrasound image feed on a secondarydevice (called a receiving device herein). For example, the receivingdevice may be a larger display (e.g., a television or monitor) suitablefor viewing by a larger audience. Providing viewing access may behelpful in an educational setting where multiple students can view theultrasound image feed more easily on the receiving device.

In situations where the receiving device includes a display, someexisting solutions use screen mirroring technology to provide viewingaccess of the ultrasound image feed. Screen mirroring may replicate theultrasound image feed being displayed from a primary display device to asecondary display. However, screen mirroring typically requires theprimary display to receive ultrasound image data, process it fordisplay, and further transmit the ultrasound image feed to the secondarydisplay. This places a large processing burden on the primary displaydevice and may slow down its processing. Also, many screen mirroringservices require the primary display and secondary display to be on thesame local area network (LAN) to allow the primary display to discoverthe secondary display. This may introduce an inconvenient step ofjoining a LAN that needs to be performed at the secondary display priorto viewing the ultrasound image feed thereon.

There is thus a need for improved ultrasound systems and methods ofestablishing a secondary connection at an ultrasound imaging machinethat provide access to an ultrasound image feed. The embodimentsdiscussed herein may address and/or ameliorate at least some of theaforementioned drawbacks identified above. The foregoing examples of therelated art and limitations related thereto are intended to beillustrative and not exclusive. Other limitations of the related artwill become apparent to those of skill in the art upon a reading of thespecification and a study of the drawings herein.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting examples of various embodiments of the present disclosurewill next be described in relation to the drawings, in which:

FIG. 1 shows a functional block diagram of an ultrasound system,according to at least one embodiment of the present disclosure;

FIG. 2 shows a flowchart diagram with acts of establishing a secondaryconnection at an ultrasound imaging machine for providing access to anultrasound image feed, according to at least one embodiment of thepresent disclosure;

FIGS. 3 and 4 show example user interfaces on a multi-use display deviceand a receiving device that allow the receiving device to establish asecondary connection with an ultrasound machine that is alreadyconnected to the multi-use display device, according to at least oneembodiment of the present disclosure;

FIGS. 5, 7, and 9 show flowchart diagrams of acts for establishing asecondary connection at an ultrasound imaging machine by providingconnection parameters over a second communications protocol, accordingto several embodiments of the present disclosure;

FIGS. 6 and 8 show example user interfaces on a multi-use display deviceand a receiving device that allow the receiving device to obtainconnection parameters over a second communications protocol, accordingto several embodiments of the present disclosure;

FIG. 10 is a diagram showing an ultrasound imaging machine having afirst link-layer connection for receiving commands that control anultrasound image feed, and multiple second link-layer connections forproviding access to the ultrasound image feed, according to at least oneembodiment of the present disclosure; and

FIG. 11 is a diagram showing an ultrasound imaging machine having afirst link-layer connection for receiving commands that control anultrasound image feed, and a second link-layer connection with areceiving device having a port connected to a simple display, accordingto at least one embodiment of the present disclosure.

DETAILED DESCRIPTION

In a first broad aspect of the present disclosure, there is provided amethod of providing viewing access to an ultrasound image feed generatedat an ultrasound imaging machine, the method comprising, at a multi-usedisplay device: forming a first link-layer connection with theultrasound image machine, the first link-layer connection being fortransmitting commands that control imaging parameters of the ultrasoundimage feed; determining link-layer connection parameters that allow theultrasound imaging machine to form a second link-layer connection with areceiving device, the receiving device having no link-layer connectionwith the ultrasound imaging machine; and providing the connectionparameters to the receiving device, wherein the receiving device forms asecond link-layer connection with the ultrasound imaging machine usingthe connection parameters, the second link-layer connection being usedfor receiving, at the receiving device, the ultrasound image feedcontrolled by the multi-use display device.

In some embodiments, the first link-layer connection and the secondlink-layer connection are each formed using a wireless local areanetwork (WLAN) connection. In some embodiments, the connectionparameters comprise: a service set identifier (SSID) associated with theWLAN, and a password for connecting to the WLAN. In some embodiments,the receiving device comprises another multi-use display device.

In some embodiments, the receiving device comprises a dongle having aport for connecting an image output device, wherein one or moreultrasound images from the ultrasound image feed received at thereceiving device is provided to the image output device via the port. Insome embodiments, the commands that control imaging parameters of theultrasound image feed comprise a signal marking the one or moreultrasound images from the ultrasound image feed to be provided to theimage output device via the port, and the signal is transmitted from theultrasound imaging machine to the receiving device. In some embodiments,a signal is transmitted from the multi-use display device to thereceiving device, and the signal marks the one or more ultrasound imagesfrom the ultrasound image feed to be provided to the image output devicevia the port.

In some embodiments, the method further comprises providing theconnection parameters via an optical communication channel. In someembodiments, the optical communications channel comprises: displaying abarcode embedding the connection parameters, the barcode for reading bya barcode reader on the receiving device.

In some embodiments, the providing the connection parameters to thereceiving device comprises communicating the connection parameters tothe receiving device via a contactless communication channel. In someembodiments, the contactless communication channel comprises a nearfield communication (NFC) communication channel, and the method furthercomprises: configuring an NFC integrated circuit (IC) to transmit theconnection parameters for reading by a NFC reader on the receivingdevice.

In some embodiments, the first link-layer connection is formed using afirst communications protocol, and prior to providing the connectionparameters to the receiving device, the method further comprises:determining availability of a receiving device to receive the ultrasoundimage feed, the determining being performed using a secondcommunications protocol different from the first communicationsprotocol, wherein the providing the connection parameters is performedover the second communications protocol. In some embodiments, the firstcommunications protocol comprises a Wi-Fi™ protocol, and the secondcommunications protocol comprises a Bluetooth™ protocol.

In some embodiments, the first link-layer connection is formed using afirst communications protocol, and prior to providing the connectionparameters to the receiving device, the method further comprises:advertising availability of the multi-use display device to provide theconnection parameters, the advertising being performed using a secondcommunications protocol different from the first communicationsprotocol, wherein the providing the connection parameters is performedover the second communications protocol. In some embodiments, the firstcommunications protocol comprises a Wi-Fi™ protocol, and the secondcommunications protocol comprises a Bluetooth™ protocol.

In another broad aspect of the present disclosure, there is provided amethod of providing viewing access to an ultrasound image feed generatedat an ultrasound imaging machine, the method comprising, at theultrasound imaging machine: forming a first link-layer connection with amulti-use display device, the first link-layer connection being forreceiving commands that control imaging parameters of the ultrasoundimage feed, wherein the multi-use display device: determines link-layerconnection parameters that allow the ultrasound imaging machine to forma second link-layer connection with a receiving device, the receivingdevice having no link-layer connection with the ultrasound imagingmachine, and provides the connection parameters to the receiving device;based on the connection parameters, receiving a request from thereceiving device to form the second link-layer connection; forming thesecond link-layer connection with the receiving device; and providingviewing access of the ultrasound image feed to the receiving deviceusing the second link-layer connection.

In some embodiments, the first link-layer connection and the secondlink-layer connection are each formed using a wireless local areanetwork (WLAN) connection. In some embodiments, the connectionparameters comprise: a service set identifier (SSID) associated with theWLAN, and a password for connecting to the WLAN.

In some embodiments, the receiving device comprises a dongle having aport for connecting an image output device, wherein one or moreultrasound images from the ultrasound image feed received at thereceiving device is provided to the image output device via the port. Insome embodiments, the commands that control imaging parameters of theultrasound image feed comprise a signal marking the one or moreultrasound images from the ultrasound image feed to be provided to theimage output device via the port, and the signal is transmitted from theultrasound imaging machine to the receiving device.

In some embodiments, the first link-layer connection is formed using afirst communications protocol, and prior to providing the connectionparameters to the receiving device, the multi-use display device:advertises availability of the multi-use display device to provide theconnection parameters to the receiving device, the advertising beingperformed using a second communications protocol different from thefirst communications protocol, wherein the providing the connectionparameters is performed over the second communications protocol. In someembodiments, the first communications protocol comprises a Wi-Fi™protocol, and the second communications protocol comprises a Bluetooth™protocol.

In another broad aspect of the present disclosure, there is provided amethod of providing viewing access to an ultrasound image feed generatedat an ultrasound imaging machine, the method comprising, at theultrasound imaging machine: forming a first link-layer connection with amulti-use display device, the first link-layer connection being forreceiving commands that control imaging parameters of the ultrasoundimage feed, wherein the first link-layer connection is formed using afirst communications protocol; advertising availability of viewingaccess to the ultrasound image feed, the advertising being performedusing a second communications protocol different from the firstcommunications protocol, wherein the advertising includes connectionparameters that allow the ultrasound imaging machine to form a secondlink-layer connection with a receiving device using the firstcommunications protocol; based on the connection parameters, receiving arequest from the receiving device to form the second link-layerconnection, the request being received using the first communicationsprotocol; forming the second link-layer connection with the receivingdevice; and providing viewing access of the ultrasound image feed to thereceiving device using the second link-layer connection.

In another broad aspect of the present disclosure, there is provided amethod of obtaining viewing access to an ultrasound image feed generatedat an ultrasound imaging machine, the method comprising, at a receivingdevice: determining link-layer connection parameters from one of: theultrasound imaging machine and a multi-use display device, wherein theultrasound imaging machine has a first link-layer connection with themulti-use display device, and the first link-layer connection is for themulti-use display device to transmit commands to the ultrasound imagingmachine to control imaging parameters of the ultrasound image feed;based on the connection parameters, sending a request to the ultrasoundimaging machine for the ultrasound imaging machine to form a secondlink-layer connection with the receiving device; forming the secondlink-layer connection with the ultrasound imaging machine; andreceiving, via the second link-layer connection, the ultrasound imagefeed generated at the ultrasound imaging machine.

In some embodiments, the receiving device comprises another multi-usedisplay device, and the method further comprises displaying theultrasound image feed at the receiving device.

In some embodiments, the receiving device comprises a dongle having aport for connecting an image output device, and wherein the methodfurther comprises: providing one or more ultrasound images from theultrasound image feed received at the receiving device to the imageoutput device via the port.

In some embodiments, the image output device comprises a simple display.In some embodiments, the image output device comprises an ultrasoundimage printer.

In some embodiments, the commands that control imaging parameters of theultrasound image feed comprise a signal marking the one or moreultrasound images from the ultrasound image feed to be provided to theimage output device via the port, and prior to providing the one or moreultrasound images to the image output device, the method furthercomprises: receiving the signal from the ultrasound imaging machine; andbased on the signal, marking the one or more ultrasound images forproviding to the image output device via the port.

In some embodiments, prior to providing the one or more ultrasoundimages to the image output device, the method further comprises:receiving a signal from the multi-use display device, the signal markingthe one or more ultrasound images from the ultrasound image feed to beprovided to the image output device via the port; and based on thesignal, marking the one or more ultrasound images for providing to theimage output device via the port.

For simplicity and clarity of illustration, where consideredappropriate, reference numerals may be repeated among the figures toindicate corresponding or analogous elements or steps. In addition,numerous specific details are set forth in order to provide a thoroughunderstanding of the exemplary embodiments described herein. However, itwill be understood by those of ordinary skill in the art that theembodiments described herein may be practiced without these specificdetails. In other instances, certain steps, signals, protocols,software, hardware, networking infrastructure, circuits, structures,techniques, well-known methods, procedures and components have not beendescribed or shown in detail in order not to obscure the embodimentsgenerally described herein.

Furthermore, this description is not to be considered as limiting thescope of the embodiments described herein in any way. It should beunderstood that the detailed description, while indicating specificembodiments, are given by way of illustration only, since variouschanges and modifications within the scope of the disclosure will becomeapparent to those skilled in the art from this detailed description.Accordingly, the specification and drawings are to be regarded in anillustrative, rather than a restrictive, sense.

Referring to FIG. 1, shown there generally as 100 is a functional blockdiagram of an ultrasound system, according to at least one embodiment ofthe present disclosure. Ultrasound imaging system 100 may include amulti-use display device 102, an ultrasound imaging machine 104, and areceiving device 106. For ease of reference, the ultrasound imagingmachine 104 may also be referred to herein simply as an “ultrasoundmachine”. Likewise, the multi-use display device 102 may also bereferred to herein as the “display device”. In various instances, themulti-use display device 102 may also be referred to herein as the“controlling device” because aspects of the ultrasound image feed may becontrolled thereon.

The multi-use display device 102 may include a processor 120, memory124, user interface 126, and an external interface 122. Processor 120may be a central processing unit (CPU) or may be a low power/mobilespecific processor. Processor 120 may be coupled with memory 124. Memory124 may include storage for program and program operating code. One ormore programs or applications (e.g., “apps”) 124A in memory 124 maycoordinate interactions of multi-use display device 102 with ultrasoundimaging machine 104 and/or receiving device 106. In some embodiments,the multi-use display device 102 may be a tablet computer or a mobiledevice running iOS™, Android™ or other suitable operating system.

User interface 126 may be coupled with processor 120 and may includeboth the software and hardware components necessary to interface with auser of the multi-use display device 102. User interface 120 may includephysical input components such as a touch-sensitive display screen,keyboard, microphone, or function buttons. User interface 120 mayfurther include output devices such as a color, grayscale, or black andwhite display screen, audio speaker/output, vibrating and/orlight-emitting diode (LED) indicators.

External interface 122 may be coupled with processor 120 and may provideconnectivity of multi-use display device 102 with ultrasound imagingmachine 104 through communication link 108A. External interface 122 mayalso be operable to communicate with another device, such as a webserver and/or receiving device 106 (e.g., via communication link 108C),for example.

Processor 120 may generate control commands to control an operation ofultrasound imaging machine 104 according to information that is providedvia user interface 126. The commands may control ultrasound imagingmachine 104 to generate ultrasound signals, and/or control how theultrasound imaging machine 104 handles transmission and reception of theultrasound signal for generating an ultrasound image feed. For example,commands may be inputted via the user interface 126 at the multi-usedisplay device 102 to control imaging parameters of the ultrasound imagefeed being generated at the ultrasound imaging machine 104. Based on theimaging parameters, the ultrasound imaging machine 104 may transmitultrasound signals to a target object and receive echoes in response togenerate an ultrasound image in the ultrasound image feed. Imagingparameters include factors that affect how ultrasound signals aretransmitted and received. For example, these may include the ultrasoundsequence, focus of ultrasound signals, imaging depth, and/or frequencyof the ultrasound signals.

Throughout the description herein, a “target object” may be a targetinanimate object or a target animate object, which is displayed via animage. Also, the target object may be a part of a human body and mayinclude the liver, the heart, the womb, the brain, the breast, theabdominal region, or the like, a fetus, or a cross-section of a part ofthe human body. Throughout the following description, a “user” may be amedical expert including a doctor, a nurse, a medical laboratorytechnologist, a sonographer, or the like.

Additionally or alternatively, processor 120 may control wirelesscommunication with ultrasound imaging machine 104, and may controlgeneration and display of an ultrasound image on a display of userinterface 126 based on ultrasound image data provided from ultrasoundimaging machine 104. As discussed below, processor 120 may also controlwireless communication with receiving device 106.

Still referring to FIG. 1, ultrasound imaging machine 104 may include aprocessor 140, memory 144, imaging unit 146, pairing unit 148, and acommunication unit 142. Processor 140 may include a CPU, a lowpower/mobile specific processor, a field programmable gate array, acombination of two or more of these or the like.

Imaging unit 146 may be operable to acquire ultrasound image data of atarget object based on control signals from processor 140. Imaging unit146 may include a transmitter for generating ultrasound energy, and areceiver for receiving ultrasound energy reflected from the targetobject. Imaging unit 146 may include an analog-to-digital converter(ADC) for digitizing the received ultrasound energy into digitalultrasound data. Imaging unit 146 may also include one or morebeamformers to combine and focus the received ultrasound energy along adesired scanline. Imaging unit 146 may further include a signalprocessor to apply filtering or compression to the ultrasound imagedata.

In various embodiments, imaging unit 146 may include a scan converterfor converting the ultrasound image data into a specific display format.However, in some embodiments, a scan converter may not be provided atthe ultrasound imaging machine 104. Instead, a scan converter (orappropriate software instructions for performing scan conversion) may beprovided at the multi-use display device 102 and/or the receiving device106. As discussed below with respect to FIG. 10, the multi-use displaydevice 102 and a given receiving device 106 may have differentconfigurations (e.g., a display device 102 may be a tablet computer,whereas a receiving device 106 may be a smartphone or a televisiondisplay). Performing scan conversion at the destination device insteadof at the ultrasound imaging machine 104 may allow for adapting of anultrasound image feed to the display format of the destination device(e.g., adapting for different aspect ratios and/or resolutions of thedifferent displays).

Referring still to FIG. 1, processor 140 may be coupled with memory 144.Memory 144 may include storage for software 144A (e.g., program and/orprogram operating code). One or more programs in memory 144 maycoordinate the operation of ultrasound imaging machine 104 as describedherein. Memory 144 may also be used to store information aboutultrasound imaging machine 104 and/or ultrasound image data.

Pairing unit 148 may be operable to establish communication link 108Abetween communication unit 142 and external interface 122 of multi-usedisplay device 102. Communication unit 142 may include one or morewireless transceivers. As discussed below, the pairing unit 148 may alsobe operable to establish communication link 108B between thecommunication unit 142 and the external interface 162 of the receivingdevice 106, to provide access to the ultrasound image feed beingcontrolled by the multi-use display device 102.

Ultrasound imaging machine 104 may have any of a wide range of varioussizes and configurations. For example, ultrasound imaging machine 104may be handheld or hand carried. Alternatively, ultrasound imagingmachine 104 may be in a laptop form factor or a more traditionalcart-based form factor. In some embodiments, ultrasound imaging machine104 may have the form of hand-held, battery-powered probes. In anexample embodiment, the ultrasound imaging machine 104 may be providedin the form of a portable handheld ultrasound scanner that cancommunicate wirelessly to a multi-use display device 102 and/or one ormore receiving devices 106.

Referring still to FIG. 1, receiving device 106 may include a processor160, memory 164, and an external interface 162. Processor 160 may be acentral processing unit (CPU) or may be a low power/mobile specificprocessor. Processor 160 may be coupled with memory 164. Memory 164 mayinclude storage for firmware and/or software 164A (e.g., program andprogram operating code), depending on the configuration of the receivingdevice 106. The firmware/software 164A in memory 164 may coordinateinteractions of receiving device 106 with ultrasound imaging machine 104and/or the controlling device 102.

Receiving devices 106 may take different forms in various embodiments.Depending on the configuration, a receiving device 106 may have one ormore output components. For example, a receiving device 106 may includea display 166 and/or a port 168. These elements are optional and may notnecessarily be included with all receiving devices 106. As such, theyare shown in dotted outline in FIG. 1. In an example scenario, thereceiving device 106 may be a dongle having a port 168 for connecting animage output device such as a simple display (e.g., a larger externaltelevision) or an ultrasound image printer.

In another example scenario, where the receiving device 106 includes adisplay 166, the receiving device 106 may be similar to the multi-usedisplay device 102. In such case, software 164A executing on thereceiving device 106 may be substantially similar to software 124Aexecuting on the display device 102. For example, the same application(e.g., downloadable from an application store available on a mobiledevice operating system such as iOS™ or Android™) may execute on boththe display device 102 and the receiving device 106, and the applicationcan be configurable to operate in both a regular mode on the displaydevice 102 to control operation of the ultrasound imaging machine 104,and a viewing mode on the receiving device 106 for receiving view-onlyaccess to an ultrasound image feed generated by the ultrasound imagingmachine 104.

External interface 162 of receiving device 106 may be coupled withprocessor 160, and may provide connectivity of the receiving device 106to the ultrasound imaging machine 104 through communication link 108B.The receiving device 106 may receive the ultrasound image feed throughexternal interface 162. External interface 162 may also be operable tocommunicate with another device, such as a web server or display device102 (e.g., through communication link 108C), for example.

The display 166 and/or the port 168 may be coupled with processor 160 sothat one or more images of the ultrasound image feed may be outputtedthereto. In various embodiments, the receiving device 106 may alsoinclude a user interface (not shown on receiving device 106 in FIG. 1)similar to user interface 126 of multi-use display device 102 describedabove. This user interface may be a part of, or separate from, thedisplay 166.

Input may be provided via a user interface on receiving device 106 tocause the processor 160 to receive connection parameters to form thecommunication link 108B with the ultrasound imaging machine 104. Thiscommunication link 108B may allow the receiving device 106 to receivethe ultrasound image feed being generated at the ultrasound imagingmachine 104 (and controlled at the multi-use display device 102). Theprocessor 160 may process the ultrasound image feed to, for example,output the ultrasound image feed for display on the display 166 and/oroutput one or more images from the ultrasound image feed to an imageoutput device via port 168.

In various embodiments, the ultrasound image feed being provided to thereceiving device 106 may be similar to the one provided to the multi-usedisplay device 102. For example, the ultrasound image feed transmittedfrom the ultrasound imaging machine 104 may be in pre-scan-convertedformat (e.g., polar coordinates), so that scan conversion is performedby processor 120 and processor 160 on the multi-use display device 102and the receiving device 106 respectively (e.g., scan converted to be incartesian coordinates suitable for each respective device). Configuringthe ultrasound image feed transmitted from the ultrasound imagingmachine 104 to be in pre-scan converted format may allow such format tobe the same regardless of the destination device (e.g., the same formatcan be used whether it is transmitted to the multi-use display device102 or the receiving device 106). This may allow the ultrasound imagingmachine 104 to reuse the same software code 144A that transmits theultrasound image feed to the multi-use display device 102 whentransmission is being made to the receiving device 106. This may reducecomplexity of the software code 144A at the ultrasound imaging machine104. Also, as noted, performing scan conversion at the destinationdevice may allow the same ultrasound image feed to be adapted to variousdisplay formats of either the display device 120 and/or multiplereceiving devices 106.

Referring still to FIG. 1, it can be noted that ultrasound imagingmachine 104 may establish multiple communication links with externaldevices. As shown, the ultrasound imaging machine 104 may establish afirst communication link 108A with multi-use display device 102. Thiscommunication link 108A may allow the multi-use display device 102 totransmit commands to the ultrasound imaging machine 104, and theultrasound imaging machine 104 to transmit an ultrasound image feed fromthe ultrasound imaging machine 104 to the multi-use display device 102.A second communication link 108B may allow the ultrasound imagingmachine 104 to provide view-only access of an ultrasound image feed toone or more receiving devices 106.

In various embodiments, the communication unit 142 of ultrasound imagingmachine 104 may include suitable hardware to communicate using more thanone communications protocol. Corresponding external interfaces 122, 162on multi-use display device 102 and/or receiving device 106 respectivelymay also be configured to communicate using more than one communicationsprotocol so that communications may take place over communication links108A, 108B using multiple communications protocols.

For example, in cases of wireless transmission of an ultrasound imagefeed, a high-bandwidth connection such as Wi-Fi™ may be desired. Whilesome communications protocols (e.g., Bluetooth™) may allow for ease ofdiscoverability, these protocols typically have a lower bandwidth thatmay not be sufficient to transmit a high-quality ultrasound image feed(e.g., Bluetooth™ bandwidth may not exceed one (1) megabyte per second).In some embodiments, the primary link between an ultrasound imagingmachine 104 and a multi-use display device 102 may be achieved using acommunications protocol (e.g., Wi-Fi™) that has sufficient bandwidth toallow the transmission of the ultrasound image feed from the ultrasoundimaging machine 104 to the multi-use display device 102.

To allow the receiving device 106 to receive the ultrasound image feed,the receiving device 106 may also need to form a communication link withthe ultrasound imaging machine 104 using an analogous communicationsprotocol that has sufficient bandwidth. However, the steps for thereceiving device 106 to discover and establish a connection with anultrasound machine 104 using the higher-bandwidth communicationsprotocol may not be as straightforward as using the narrower-bandwidthprotocol.

For example, in the case where the higher-bandwidth communicationsprotocol is Wi-Fi™ and the receiving device 106 had no previous Wi-Fi™connection with the ultrasound imaging machine 104, a user may berequired to interact with the settings menu of a receiving device 106 toselect a Service Set Identifier (SSID) of the Wireless Local AreaNetwork (WLAN) being broadcasted by the ultrasound machine 104. Then, auser may need to type in a password to join the WLAN. This may causeinconvenience for a user.

As will be understood by persons skilled in the art, the bandwidth of acommunications protocol may typically be a characteristic of thephysical and data link layers of the Open Systems Interconnection (OSI)model for organizing functions of data communications. For example, WLANconnections may operate at the physical and link-layers of the OSImodel. The present embodiments generally relate to methods of providinglink-layer connection parameters (e.g., an SSID and associated password)to a receiving device 106 to facilitate ease of establishing thelink-layer connection between the receiving device 106 and theultrasound machine 104.

Unlike screen-mirroring techniques between devices that can discovereach other if they are already connected via data and data link-layerconnections, the establishment of a link-layer connection at lowerlevels of the OSI model may require the receiving device 106 to be inpossession of the link-layer connection parameters. The presentembodiments facilitate providing the connection parameters to thereceiving device 106. Notably, in situations where a WLAN communicationsprotocol is used to form the communications link 108A between thedisplay device 102 and the ultrasound machine 104, the display device102 may not be able to use many existing screen mirroring technologiesbecause the display device 102 may be only able to form a single Wi-Fi™connection, and that connection is needed to be formed with theultrasound machine 104. Thus, the display device 102 may not be able tojoin another local WLAN hotspot to take advantage of existing screenmirroring technologies. Furthermore, screen mirroring technologies maynot be a good solution for providing an ultrasound image feed from thedisplay device 102 to the receiving device 106 because even though ahigher bandwidth communications protocol is being used, the protocol maynot have sufficient bandwidth to allow the display device 102 to bothreceive the ultrasound image data for display, and further forward suchdata to the receiving device 106.

Several example communication protocols such as Bluetooth™ and Wi-Fi™have been discussed above. However, other types of communicationsprotocol may also be used with the methods described herein. Forexample, other communications that may be used include: a Bluetooth™ lowenergy (BLE) connection, ZigBee™, Wi-Fi Direct (WFD), ultra wideband(UWB), infrared data association (IrDA), near field communication (NFC),wireless broadband internet (Wibro), world interoperability formicrowave access (WiMAX), shared wireless access protocol (SWAP), radiofrequency (RF) communications, radio frequency identification (RFID),and the like.

The embodiments described herein generally allow the receiving device106 to establish a second communications link 108B with the ultrasoundimaging machine 104 for receiving the ultrasound image feed beingcontrolled by, and transmitted to, the multi-use display device 102. Asdescribed herein, the connection parameters for establishing the secondcommunications link 108B may be provided from the multi-use displaydevice 102 to the receiving device 106 so that the receiving device 106may directly establish the second communications link 108B with theultrasound imaging machine 104.

Referring to FIG. 2, shown there generally as 200 is a flowchart diagramwith acts of establishing a secondary connection at an ultrasoundimaging machine for providing access to an ultrasound image feed,according to at least one embodiment of the present disclosure. Themethod of FIG. 2 shows interaction amongst the ultrasound imagingmachine 104, the multi-use display device 102, and the receiving device106 shown in FIG. 1. In describing the method shown in FIG. 2, referencemay also be made to the example user interfaces shown in FIGS. 3 and 4.

At 202, the ultrasound imaging machine 104 may broadcast link-layerconnection parameters. For example, the link-layer connection may be aWi-Fi™ connection that allows for formation of a Wireless Local AreaNetwork (WLAN) amongst the ultrasound imaging machine 104, the multi-usedisplay device 102, and/or the receiving device 106. The connectionparameters may include a service set identifier (SSID) associated withthe WLAN, and a password for connecting to the WLAN. At 204, the displaydevice 102 may receive the link-layer connection parameters from theultrasound imaging machine 104.

At 206, the display device 102 may request to form the link-layerconnection with the ultrasound machine 104 using the connectionparameters received at act 204. In various embodiments, the displaydevice 102 may display the connection parameters, and initiation of therequest to form the link-layer connection may result from receipt ofuser input at the display device 102. In some embodiments, the displaydevice 102 may automatically request to form the link-layer connection102 based on connection parameters received at act 204. For example, inscenarios where the link-layer connection is a Wi-Fi™ connection, theautomatically forming of the connection may be implemented by accessinga Wi-Fi™ auto-join application programming interface (API) available onthe operating system of the display device 102.

At 208, the ultrasound imaging machine 104 may receive the request toform a link-layer connection with the display device 120. At acts210-212, based on the request received at act 208, the ultrasoundimaging machine 104 may form a first link-layer connection with amulti-use display device 102. This first-link layer connection may allowthe ultrasound imaging machine 104 to receive commands that controlimaging parameters of the ultrasound image feed being generated. Forexample, these imaging parameters may include imaging depth, focus,and/or anatomy pre-sets. Communications for transmitting commands andthe updating of the ultrasound image feed may occur at acts 214-216.These acts are shown in dotted outline to indicate they are optional, asacts 214-216 may not necessarily be performed prior to acts 218-236.

At 218, the display device 102 may determine link-layer connectionparameters that allow the ultrasound imaging machine 104 to form asecond link-layer connection 108B (as shown in FIG. 1) with a receivingdevice 106. As noted, in example embodiments where the link-layerconnection is a Wi-Fi™ connection, these connection parameters mayinclude a SSID and a password for joining the WLAN identified by theSSID. Additionally or alternatively, the connection parameters mayinclude network-layer parameters such as an Internet Protocol (IP)address and port number. After a link-layer connection has beenestablished, the network-layer parameters may be used by softwareexecuting on the receiving device 106 to also form a network-layerconnection to the ultrasound imaging machine 104 that allows thereceiving device 106 to receive and process the ultrasound image feed.

Notably, the receiving device 106 may have no previous link-layerconnection with the ultrasound imaging machine 104 such that theconnection parameters for establishing the second link-layer connection108B would not be cached or otherwise available at the receiving device106. For example, this may occur in an educational setting wherestudents may use their own receiving devices 106 to receive anultrasound image feed from an ultrasound imaging machine 104 beingoperated by an instructor.

Another scenario where the present embodiments may be desirable is whenthe ultrasound imaging machine 104 is provided in an ultraportable form(e.g., in the form of a wireless handheld scanner that connects to anexternal display device 102 for receiving commands and displaying anultrasound image feed). The ultraportable characteristics of anultrasound imaging machine 104 may allow it to be more easilytransported to multiple locations (e.g., it may accompany a physician orother ultrasound operator to multiple hospitals or clinics) such thatultrasound imaging machine 104 may frequently connect to new receivingdevices 106 at those varying locations.

In a further scenario, the ultrasound imaging machine 104 may be used ina clinic, and new patients may frequently connect their own receivingdevice 106 to the ultrasound machine 104 being used at a clinic to viewthe ultrasound images being taken. For example, this may be desirable inobstetrics/gynaecology specialties where an expecting mother may desireto hold a receiving device 106 in their hands during an examination tomore easily view ultrasound images being obtained of a fetus. As newpatients come into the clinic, they may use their own mobile devices asreceiving devices 106 in this manner. This may result in many receivingdevices 106 with no previous link-layer connection frequently attemptingto form new connections with an ultrasound imaging machine 104 beingused at the clinic, such that the ease of providing connectionparameters in the manner described herein may be particularly desirable.

Referring still to FIG. 2, at 220, the display device 120 may providethe connection parameters to the receiving device 106. This may beperformed in various ways. In some embodiments, the connectionparameters may be provided via an optical communication channel. Forexample, this may involve the display device 120 displaying a barcodeembedding the connection parameters so that the barcode can be read by abarcode reader on the receiving device 106.

Referring simultaneously to FIG. 3, shown there generally as 300 areexample user interfaces on a multi-use display device 102 and areceiving device 106 that allow the receiving device 106 to establish asecondary connection with an ultrasound machine 104 connected to themulti-use display device 102, according to at least one embodiment ofthe present disclosure. As noted above, in some example embodiments, asingle downloadable ultrasound application may be operable in multiplemodes: a regular mode that establishes a primary connection with anultrasound imaging machine 104 to control imaging parameters, and aview-only mode that establishes a secondary connection with theultrasound imaging machine 104 for simply receiving (but notcontrolling) the ultrasound image feed. Depending on the mode theapplication is executing, a given mobile computing device may consideredeither a display device 102 or a receiving device 106 as describedherein. Alternatively, dedicated separate applications may be providedfor controlling imaging parameters and obtaining view-only access.

As shown in FIG. 3, the display device 102 may be operating in theregular mode, and is configured to display a two-dimensional QuickResponse (QR) code 302 that embeds the connection parameters. As shown,a QR code is shown; however, in various embodiments, other types ofbarcodes may also be used. In the user interface shown in the displaydevice 102, the term “Listener” is also used to refer to the receivingdevice 106.

The receiving device 106 may have a camera or other optical sensor thatallows it to read the barcode 302 being displayed at the display device102. In the example illustrated in FIG. 3, a software applicationexecuting on the receiving device 106 may be operating in a view-onlymode that accesses a camera available on the receiving device 106 toconfigure it to be used as a barcode reader. For example, the userinterface on the receiving device 106 may overlay the images from thecamera with a barcode reader that requests for alignment of a displayedbarcode 302 within a frame 310. Once the barcode 302 is read at thereceiving device 106, the connection parameters may be determined by thereceiving device 106. In an example embodiment, the receiving device 106may provide the barcode reader by implementing a barcode scanninglibrary such as the “ZXing” (“Zebra Crossing”) library.

In FIG. 3, the display device 102 also shows instructions 304 formanually establishing a second link-layer connection with the ultrasoundimaging machine 104 (e.g., the SSID and password for establishing aWi-Fi™ connection with the ultrasound imaging machine 104). Instead ofscanning the barcode using the user interface shown in FIG. 3, a user ofthe receiving device 106 may use these instructions to manually identifythe SSID in the Wi-Fi™ settings of a receiving device 106 and connect tothe ultrasound imaging machine 104 using the password indicated.However, manual connection is cumbersome, and providing the connectionparameters via the barcode may increase ease of use.

Also shown in FIG. 3 are the transport-layer parameters such as an IPaddress and port number. In various embodiments, these parameters mayalso be embedded in the barcode 302 to allow the receiving device 106 toform a transport-layer connection with the ultrasound imaging machine104. In FIG. 3, the user interface on the receiving device 106 alsoprovides user interface text fields that allow for manual entry of theIP address and port number if the link-layer connection was beingestablished manually.

The embodiment shown in FIG. 3 is configured to allow for unicasttransmission between the ultrasound imaging machine 104 and a receivingdevice 106, such that the receiving device 106 may need informationabout the IP address and port number of the ultrasound machine 104.However, additionally or alternatively, the ultrasound machine 104 maybe configured to use an IP multicast protocol for providing theultrasound image feed to receiving devices 106. In such case, thereceiving device 106 may be preconfigured with known IP multicastaddresses, such that this information need not be provided to thereceiving device 106.

Referring back to FIG. 2, another way of implementing act 220 is toprovide the connection parameters to the receiving device 106 bycommunicating via a contactless communication channel. In someembodiments, the contactless communication channel may include a nearfield communication (NFC) communication channel. In this case, act 220may involve configuring an NFC integrated circuit (IC) on the displaydevice 102 to transmit the connection parameters for reading by a NFCreader on the receiving device 106.

Referring simultaneously to FIG. 4, shown there generally as 400 areexample user interfaces on a multi-use display device 102 and areceiving device 106 that allow the receiving device 106 to establish asecondary connection with an ultrasound machine 104 connected to themulti-use display device 102, according to at least one other embodimentof the present disclosure. As shown in FIG. 4, when the display device102 is configuring the NFC IC to transmit the connection parameters inthis manner, the user interface 126 (as shown in FIG. 1) may beconfigured to display a graphic 402 and associated text that informs auser to hold a receiving device 106 nearby to receive the connectionparameters. When configured to be in a view-only mode for receiving anultrasound image feed, the receiving device 106 may similarly show agraphic 410 to inform a user of the receiving device 106 to bring thereceiving device 106 near the display device 102 so that it can activateits NFC reader to read the connection parameters from the display device102. As compared to FIG. 3, the example user interfaces on the displaydevice 102 and the receiving device 106 do not show the instructions 304for manually establishing a second link-layer connection with theultrasound imaging machine 104. Users may then be expected to use theNFC IC and reader to provide the connection parameters from the displaydevice 102 to the receiving device 106.

Referring back to FIG. 2, at act 222, the receiving device 106 mayreceive the link-layer connection parameters. As discussed above, insome embodiments, this may be performed via the reading of barcode 302(as shown in FIG. 3) or via an NFC reader (as shown in FIG. 4).

At act 224, based on the connection parameters, the receiving device 106may send a request to the ultrasound imaging machine 104 for theultrasound imaging machine 104 to form a second link-layer connectionwith the receiving device 106. This request may be received at theultrasound imaging machine 104 (act 226).

At act 228, the ultrasound imaging machine 104 may determine if aprimary (e.g., first) link-layer connection is already established. Asillustrated, the ultrasound imaging machine 104 may determine that afirst link-layer connection 108A (as shown in FIG. 1) has already beenestablished with the display device 102. The method may then proceed toform the second link-layer connection 108B (as shown in FIG. 1) with thereceiving device 106 (acts 230-232). However, if the ultrasound imagingmachine 104 had determined that a primary link-layer connection was notalready established, the ultrasound imaging machine 104 may determinethat the connection request is for a primary link-layer connection 108Afor controlling imaging parameters of the ultrasound image feed.

Acts 230-232 may involve a number of additional exchanges between theultrasound imaging machine 104 and the receiving device 106 that are notshown in FIG. 2. In scenarios where the link-layer connection is aWi-Fi™ connection, the receiving device 106 may automatically form theconnection with the ultrasound machine 104 by accessing a Wi-Fi™auto-join API available on the operating system of the display device102.

At 234, the ultrasound imaging machine 104 may transmit the ultrasoundimage feed (as controlled by the display device 102) to the receivingdevice 106 using the second link layer connection 108B. In this way, theultrasound imaging machine 104 may provide viewing access of theultrasound image feed to the receiving device 106. The ultrasound imagefeed may be received at the receiving device 106 (act 236).

In various embodiments, the providing of the connection parameters tothe receiving device 106 may be performed by the ultrasound imagingmachine 104 itself. For example, in some embodiments, the ultrasoundimaging machine 104 may be provided with suitable hardware componentssuch as NFC or RFID integrated circuits that, when a receiving device106 is brought within sufficient proximity, can provide the connectionparameters to the receiving device 106.

As shown in FIG. 2, the connection parameters provided by the displaydevice 102 to the receiving device at act 220 are for connecting to theultrasound imaging machine 104 using the same communications protocol asthe primary connection between display device 102 and the ultrasoundimaging machine 104 (namely, a WLAN connection). This may allow thefirst link-layer connection and the second link-layer connection to eachbe formed using the same protocol technology (e.g., a wireless localarea network (WLAN) connection). However, in other embodiments, theconnection parameters may be for allowing the receiving device 106 toconnect to the ultrasound imaging machine 104 using a communicationsprotocol that is different from the communications protocol used in thefirst link-layer connection 108A (as shown in FIG. 1).

As discussed above, the ultrasound imaging machine 104 and/or thedisplay device 102 may be provided with suitable hardware to communicateusing multiple wireless communications protocols (e.g., Bluetooth™ andWi-Fi™ radios). In some embodiments, the providing of connectionparameters to the receiving device 106 may be performed using a secondcommunications protocol (e.g., Bluetooth™) that is different from thefirst communications protocol (e.g., Wi-Fi™) used to establish theprimary communication link 108A between the ultrasound imaging machine104 and the display device 102. FIGS. 5, 7, and 9 show several exampleembodiments for how this may be performed. The methods shown in FIGS. 5and 7 involve the display device 102 providing the connection parametersto the receiving device 106 via the secondary communications protocol.The method shown in FIG. 9 involves the ultrasound imaging machine 104directly providing the connection parameters to the receiving device 106via the secondary communications protocol.

Referring to FIG. 5, shown there generally as 500 is a flowchart diagramfor acts of establishing a secondary connection at an ultrasound imagingmachine 104 by providing connection parameters over a secondcommunications protocol, according to at least one embodiment of thepresent disclosure. In FIG. 5, acts 202-216 may be performed in asimilar manner to what was described above with respect to FIG. 2. Whilenot shown in FIG. 5 for ease of illustration, an act analogous to act218 for determining the link-layer connection parameters may also beperformed in FIG. 5.

However, instead of act 220 providing the connection parameters via anoptical communications channel (e.g., barcode) or a contactlesscommunication channel (e.g., NFC), the connection parameters may beprovided via a wireless communications link 108C (as shown in FIG. 1)formed using a second communications protocol different from the firstcommunications protocol used to establish the first communications link108A between the display device 102 and the ultrasound imaging machine104.

To allow for the establishment of this second communications link 108C,at act 505, the receiving device 106 may, using the secondcommunications protocol, advertise its ability to receive an ultrasoundimage feed. For example, in scenarios where the primary communicationslink 108A is established using a Wi-Fi™ connection, the secondcommunications protocol may be a Bluetooth™ protocol and advertising maybe performed using available communications packet configurationsavailable for advertising in the Bluetooth™ protocol.

Referring simultaneously to FIG. 6, shown there generally as 600 areexample user interfaces on a multi-use display device 102 and areceiving device 106 that allow the receiving device 106 to obtainconnection parameters over a second communications protocol, accordingto at least one embodiment of the present disclosure. As illustrated inFIG. 6, the receiving device 106 may be executing an ultrasoundapplication that is being operated in a view-only mode. In this mode,the ultrasound application may be configured to advertise its ability toreceive an ultrasound image feed, and in doing so, may display a usernotification 640. When performing the advertising, the receiving device106 may be configured to display device identifier 625 that allows it tobe identified at the display device 102. A further notification 645 maybe displayed to inform the user to select the device identifier 625 onthe controlling display device 102.

Referring briefly back to FIG. 5, at 510, using the secondcommunications protocol, the display device 102 may read theadvertisement packets resulting from act 505 and determine the abilityof the receiving device 106 to receive an ultrasound image feed.

Referring again also to FIG. 6, the display device 102 may be configuredto display a user interface that shows an ultrasound image feed 615. Inthe illustrated example embodiment, the user interface may also includean imaging depth indicator 620, and an identifier 610 for the ultrasoundimaging machine 104 the display device 102 is controlling (e.g.,“Teaching Device”). In this example embodiment, the user interface ofthe display device 102 may be configured to provide a menu that allowsfor selection of a receiving device 106 to which the ultrasound imagefeed is to be transmitted.

The menu may be populated with receiving devices 106 that areadvertising their availability to receive an ultrasound image feed(e.g., over a second communications protocol). For example, in FIG. 6,since the receiving device 106 may be advertising its availability toreceive the ultrasound image feed, the device identifier 625 of thereceiving device 106 (e.g., “Student Device 2”) may appear in the menuto allow for selection at the display device 102 (e.g., by way of acheckbox beside the name). The menu may then provide a confirmatory userinterface control such as ‘OK’ button 630 to confirm that connectionparameters are to be provided to the receiving device(s) 106 with theselected device identifier 625.

Referring again back to FIG. 5, the method may then proceed to act 220where the display device 102 may use the secondary communicationsprotocol to provide the link-layer connection parameters to the selectedreceiving device(s) 106. The receiving device 106 may use the secondcommunications protocol to receive the connection parameters (act 222).The receiving device 106 may then, using the connection parametersreceived at act 222, proceed to request and form a second link-layerconnection 108B (as shown in FIG. 1) with the ultrasound imaging machine104 (acts 224-232). The ultrasound machine 104 may then transmit, andthe receiving device 106 may receive, the ultrasound image feed (acts234-236). These acts may be performed in a manner similar to what wasdescribed above in relation to FIG. 2.

Referring to FIG. 7, shown there generally as 700 is a flowchart diagramfor acts of establishing a secondary connection at an ultrasound imagingmachine 104 by providing connection parameters over a secondcommunications protocol, according to at least one embodiment of thepresent disclosure. FIG. 7 is similar to the embodiment of FIG. 5 inthat the connection parameters for the receiving device 106 to establisha link-layer connection with the ultrasound imaging machine 104 isprovided by the display device 102 via a secondary communicationsprotocol. However, unlike the method of FIG. 5, the display device 102advertises its ability to provide connection parameters instead of thereceiving device 106 advertising its ability to receive the connectionparameters.

In FIG. 7, acts 202-216 may be performed in a manner similar what isdescribed above with respect to FIG. 2. Similar to FIG. 5, in FIG. 7,act 218 from FIG. 2 has also been omitted for ease of reference. At act705, the display device 102 may, using a second communications protocol,advertise its ability to provide connection parameters that allow areceiving device 106 to connect to the ultrasound imaging machine 104.

Referring also to FIG. 8, shown there generally as 800 are example userinterfaces on a multi-use display device 102 and a receiving device 106that allow the receiving device 106 to obtain connection parameters overa second communications protocol, according to at least one embodimentsof the present disclosure. As illustrated in FIG. 8, the display device120 shows an ultrasound image feed 615 with imaging depth controls 620.Also shown is an identifier 610 for the ultrasound imaging machine 104that the display device 102 is controlling (e.g., “Teaching Scanner”).When configured to advertise the availability of the display device 102to provide connection parameters to a receiving device 106, it maydisplay user interface elements 810 that can receive user input toconfirm. User input may be received using ‘Yes’ or ‘No’ buttons 815, forexample. If a ‘Yes’ input is received, the display device 102 mayadvertise its ability to provide connection parameters using a secondcommunications protocol (e.g., Bluetooth™) different from the firstcommunications protocol (e.g., Wi-Fi™) used for the primary connectionwith the ultrasound imaging machine 104.

Referring again to FIG. 7, the method may then proceed to act 710. Atact 710, the receiving device 106 may, using the second communicationsprotocol, determine availability of the display device 102 to providethe connection parameters.

Referring again also to FIG. 8, the receiving device 106 may execute anultrasound application in a view-only mode that performs act 710. Indoing so, the receiving device 106 may provide an example user interfacesuch as is shown on receiving device 106 in FIG. 8. For example, usingthe second communications protocol, the receiving device 106 maydetermine that the display device 102 is advertising its ability toprovide connection parameters for the scanner with identifier “TeachingScanner”. This may result in the receiving device 106 displaying a userinterface control showing “Nearby receivable streams” that listsavailable nearby devices 102 advertising their ability to provideconnection parameters. As shown, the “Teaching Scanner” is shown alongwith another ultrasound imaging machine 104 with identifier “DoctorJohnson's Scanner”. The user interface on receiving device 106 mayfurther provide user interface controls 820 to select the ultrasoundmachine 104, and once selected, an option (e.g., “Connect” button 825)to confirm.

Referring back to FIG. 7, after act 710, the receiving device 106 mayestablish a connection 108C (as shown in FIG. 1) with the display device102 using the second communications protocol. The establishment of thisconnection 108C may involve the exchange of additional messages betweendisplay device 102 and receiving device 106, which are not shown herein.Using this connection 108C, the display device 102 may proceed to act220 to provide the link-layer connection parameters over the secondcommunications protocol. The link-layer connection parameters may bereceived at the receiving device 106 (act 222). Acts 224-236 of FIG. 7may then be performed in a manner similar to what was described abovefor the similarly-numbered acts in FIGS. 2 and 5.

Referring to FIG. 9, shown there generally as 900 is a flowchart diagramfor acts of establishing a secondary connection at an ultrasound imagingmachine by providing connection parameters over a second communicationsprotocol, according to at least one embodiment of the presentdisclosure. FIG. 9 illustrates a further example embodiment of how areceiving device 106 may receive connection parameters over a secondcommunications protocol that is different from a first communicationsprotocol used to establish a primary communication link between anultrasound imaging machine 104 and display device 102.

In the method of FIG. 9, the ultrasound imaging machine 104 may form afirst link-layer connection with a multi-use display device 102, thefirst link-layer connection being for receiving commands that controlimaging parameters of the ultrasound image feed. As with the embodimentsdescribed above in relation to FIGS. 5 and 7, this first link-layerconnection is formed using a first communications protocol (e.g.,Wi-Fi™). For ease of illustration, 202-212 formerly shown in FIGS. 5 and7 are omitted in FIG. 9. Acts 214 and 216 may then be performed so thatcommands may be transmitted from the display device 102, and theultrasound image feed may correspondingly be updated at the ultrasoundimaging machine 104 for transmission to the display device 102.

At 905, the ultrasound imaging machine 104 may, using a secondcommunications protocol, advertise availability for it to provideconnection parameters to a receiving device 106. Since a firstcommunications protocol (e.g., Wi-Fi™) is already used to establish aprimary connection 108A with the display device 102, using a secondcommunications protocol (e.g., Bluetooth™) different from the firstcommunications protocol may allow the availability of the connectionparameters to be advertised without disrupting the existing connectionbetween the ultrasound imaging machine 104 and the display device 102.

At 910, the receiving device 106 may, using the second communicationsprotocol, determine the availability of the ultrasound imaging machine104 to provide the connection parameters, so as to establish a wirelessconnection with the ultrasound imaging machine 104 using the secondcommunications protocol.

Referring again to FIG. 8, when the receiving device 106 determines theavailability of the ultrasound imaging machine 104 to provide theconnection parameters, the receiving device 106 may be configured toprovide a user interface similar to what is shown on receiving device106 of FIG. 8. For example, even if the ultrasound imaging machine 104is advertising the availability of connection parameters (instead of thedisplay device 102), the ultrasound imaging machine 104 may do so in asimilar manner (e.g., providing its scanner identifier “TeachingScanner”). From the perspective of the receiving device 106, it may notmatter which device (e.g., the display device 102 or the ultrasoundimaging machine 104) advertises the availability of the connectionparameters, so long as it uses the same communications protocol (e.g.,Bluetooth™). The appearance of the user interface on the receivingdevice 106 may thus be similar to what is shown in receiving device 106of FIG. 8 in that a scanner with identifier “Teaching Scanner” mayappear, even though the source of the advertisement may be from theultrasound imaging machine 104 instead of the display device 102.

Referring back to FIG. 9, a narrow-bandwidth wireless communicationslink may be formed between the ultrasound imaging machine 104 and thereceiving device 106 using the second communications protocol. At act918, the ultrasound imaging machine 104 may then provide, using thesecond communications protocol, the link-layer connection parameters forestablishing a higher-bandwidth connection that allows the receivingdevice 106 to receive the ultrasound image feed. These link-layerconnection parameters may be received at act 222.

At act 224, the receiving device 106 may, using the connectionparameters, send a request over the first communications protocol (e.g.,with the higher bandwidth) to form a link-layer connection with theultrasound imaging machine 104. For example, as discussed above, thismay involve the receiving device 106 joining a WLAN network having theSSID being broadcasted by the ultrasound imaging machine 104. Thisrequest may be received at the ultrasound imaging machine 104 (act 226).Acts 228-236 may then proceed in a manner similar to how correspondingacts in the methods of FIGS. 2, 5, and 7 were described above.

In some embodiments, the ultrasound imaging machine may be configured toestablish a secondary connection with the receiving device 106automatically. For example, in embodiments where the same applicationallows a multi-use display device to operate as both a controllingdevice 102 and a receiving device 106 (e.g., the application can beconfigured to operate in both a regular mode and a view-only mode, asdiscussed above), the application may require a user to enter logincredentials prior to permitting use of the application. In someembodiments, the user credentials may be associated with a user profilewhich, in turn, may be associated with an institution profile.

For example, an institution profile may refer to a hospital, clinic,medical practice, or any other collection of users (or single user). Insuch embodiments, when the ultrasound imaging machine 104 and/or thedisplay device 102 advertises its availability to provide connectionparameters, it may also include information related to the institutionprofile that the ultrasound machine 104 and/or the user profile of alogged-in user of the display device 102 is associated with.Additionally or alternatively, the receiving device 106 may communicatewith an external web server to lookup the institution affiliation statusof the ultrasound machine 104 and/or the user profile of a logged-inuser at the display device 102 associated with an identifier provided inthe advertisement message(s).

When the institution profile information is received at the receivingdevice 106, it may determine whether the logged-in user at the receivingdevice 106 belongs to the same institution. If so, the receiving device106 may be configured to automatically receive the connection parametersand connect to the ultrasound imaging machine 104 without additionaluser input being required at the receiving device 106.

Similarly, if the receiving device 106 is configured to advertise itsability to receive the ultrasound image feed, it may include institutioninformation in its advertisement information. Additionally oralternatively, the display device 102 (or other recipient) of theadvertisement information may communicate with an external server tolookup the institution information for a logged-in user at the receivingdevice 106. If the controlling display device 102 determines that thereceiving device 106 is associated with the same institution of alogged-in user of the controlling device 102, it may provide theconnection parameters to the receiving device 106 which in turn mayallow the receiving device 106 to connect to the ultrasound imagingmachine 104 automatically.

In addition to facilitating ease of connection, the checking of whetherthe receiving device 106 is associated with the same institution profileas the ultrasound imaging machine 104 and/or the controlling displaydevice 102 may enhance security. For example, enhanced security may beachieved by prohibiting an unauthorized receiving device 106 (e.g., thatis not associated with the same institution profile) from receiving anultrasound image feed. Additional information related to how anultrasound imaging machine 104 can be secured for use by an institutionaffiliation status can be found in Applicant's U.S. patent applicationSer. No. 15/786,279 filed Oct. 17, 2017 entitled “Systems and Methodsfor Securing Operation of an Ultrasound Scanner”, the entire contents ofwhich are hereby incorporated by reference.

Referring to FIG. 10, shown there generally as 1000 is a diagram showingan ultrasound imaging machine 104 having a first link-layer connectionfor receiving commands that control an ultrasound image feed, andmultiple second link-layer connections for receiving access to theultrasound image feed, according to at least one embodiment of thepresent disclosure.

In the example embodiment shown in FIG. 10, the ultrasound imagingmachine 104 is provided in the form of a handheld ultrasound scanner.For example, as shown, the scanner 104 is labeled “Convex”. Operation ofthe ultrasound imaging machine 104 may be controlled by a display device102 via a communication link 108A. As illustrated, the display device102 may provide user interface controls for controlling imagingparameters of the ultrasound image feed being generated at theultrasound imaging machine 104. For example, as shown, the controlsillustrated are for modifying imaging depth, focus, and frequency (e.g.,“resolution” (RES), “general” (GEN), and “penetration” (PEN) settings).Also shown in the user interface of display device 102 is the ultrasoundimage feed 615, an identifier 1002 of the ultrasound imaging machine104, and an imaging depth 1004.

FIG. 10 also illustrates the presence of multiple types of receivingdevices 106: a receiving device 106A that is another multi-use displaydevice, and a dongle 106B. When a second link-layer connection 108B isestablished between the ultrasound imaging machine 104 and the receivingdevice 106A, the receiving device 106A can also display the ultrasoundimage feed that is being controlled from the display device 102. Asshown, the user interface may be configured to be in a “viewing” mode1006 that shows the identifier 1002 (e.g., “Convex”) of the ultrasoundimaging machine 104 that is generating the received ultrasound imagefeed 615. Various characteristics of the ultrasound image feed 615 mayalso be displayed, such as the imaging depth 1004. However, since thereceiving device 106A only receives the ultrasound image feed fordisplay (without providing the ability to control imaging parameters atthe ultrasound imaging machine 104), the user interface at the receivingdevice 106A may not have the user interface controls that are shown inthe user interface of the display device 102.

As noted above, in some embodiments, the ultrasound image feed beingtransmitted from the ultrasound machine 104 may be in a pre-scanconverted format, such that scan conversion can take place at thedestination device (e.g., either display device 102 and/or receivingdevice 106). This may allow the same ultrasound image feed to bedisplayed on receiving devices 106 of different visual formats.

Referring still to FIG. 10, while no controls for controlling imagingparameters are provided at a receiving device 106A, the receiving device106A may still provide controls for manipulating how an ultrasound imagefeed can be viewed. For example, these controls may include flipping theultrasound image along an axis (e.g., either vertical or horizontal),and/or zooming in on a region of the ultrasound image feed using a readzoom operation that allows magnification of a part of the image usingexisting image data (but without requiring an updating of the imagingparameters like a wrote zoom operation).

In various embodiments, an ultrasound imaging machine 104 maysimultaneously form second link-layer connections with multiplereceiving devices 106. For example, as illustrated, the ultrasoundimaging machine 104 may also form a second link-layer connection 108B′with a receiving device 106B that is a dongle (not shown to scale inFIG. 10).

For example, the dongle 106B may have a port 168 for connecting an imageoutput device. One or more ultrasound images from the ultrasound imagefeed received at the receiving device 106B may be provided to the imageoutput device via the port 168. The image output device may be anysuitable device that can receive or process one or more images from anultrasound image feed. For example, an image output device may be amonitor (e.g., a simple display without any accompanying software forestablishing a second-link layer connection 108B directly with theultrasound imaging machine 104) or an ultrasound image printer 1050. Inan example embodiment, the ultrasound image printer 1050 may be a Sony™UP-897MD analog video printer that is designed for use with medicaldiagnostic equipment, such as ultrasound systems. The port 168 may beprovided in any form suitable for connecting to the image output device.For example, the port 168 may be any type of present or future UniversalSerial Bus (USB) connector, a MiniDisplay™ port, a High-DefinitionMultimedia Interface (HDMI) port, and/or analog audio/video connectors.In various embodiments, a dongle 106B may have multiple ports 168.

The dongle 106B may contain suitable electronics and/or softwareinstructions for performing acts described herein as being performed bya receiving device 106. In certain instances where the dongle 106B isconnected to an image output device that is not suitable for processingall the images in an ultrasound image feed, the software may beconfigured to process a marking signal that marks one or more ultrasoundimages from the ultrasound image feed that is being received by thedongle 106B. For example, in embodiments where the image output deviceis an image printer 1050, the marked one or more ultrasound images maybe sent to the printer 1050 for printing.

The marking signal may be provided to the receiving device 106B in avariety of ways. For example, the marking signal may be received at thedisplay device 102 controlling the imaging parameters of the ultrasoundimage feed. As that ultrasound image feed 615 is being displayed, userinput may be received that marks a certain displayed image. The signalmay then be transmitted as a command to the ultrasound imaging machine104, so that the ultrasound image feed may include the marking signalwhen transmitting the ultrasound image feed to the receiving device106B. By including the marking signal with the transmission of theultrasound image feed, the receiving device 106B can, based on thesignal, mark the one or more ultrasound images for providing to theimage output device (e.g., image printer 1050) via the port 168.

In another example embodiment, the marking signal may be transmitteddirectly from the display device 102 to the receiving device 106B. Forexample, in the embodiments described above in relation to FIGS. 5-8where a communications link 108C (as shown in FIG. 1) is establishedbetween the display device 102 and the receiving device 106B to allowthe display device 102 to provide connection parameters to the receivingdevice 106B, this communications link 108C may be used also to transmitthe marking signal. Once the marking signal is received, the receivingdevice 106B may mark the one or more ultrasound images for providing tothe ultrasound output device (e.g. image printer 1050) via the port 168.

The marking signal may be implemented in various ways. For example, afield or flag may be reserved in the metadata of each frame of theultrasound image feed for indicating when the marking signal has beenactivated. Additionally or alternatively, each frame of the ultrasoundimage feed may be provided with a frame number, and the marking signalmay indicate the frame number(s) of the one or more image frames to beprovided to the image output device. However, these implementations mayrequire modification of the software instructions for generating andreceiving of the ultrasound image feed.

In a further example embodiment, the marking signal may be implementedas an interrupt signal such that when the receiving device 106B receivesthe signal, it simply marks the current image frame being processed bythe receiving device 106B when the signal is received. In situationswhere the receiving device 106B and the ultrasound machine 104 are allusing a local network communications protocols (e.g., Wi-Fi™ and/orBluetooth™), any latency due to transmission of the marking signal maybe minimal. Also, the effect of any latency may not be noticed becauseit may be common for the ultrasound imaging machine 104 to be in afreeze mode such that a constant ultrasound image is being transmittedin the ultrasound image feed. Implementation of the marking signal thisway may allow for greater ease of implementation since the softwareinstructions related to the generation and transmission of theultrasound image feed may not need be modified.

In some embodiments, a controlling device 102 may be able to inputhighlights and/or other annotations on an ultrasound image that alsoappears at the receiving device 106A. In some embodiments, suchhighlighting or annotation information may be transmitted directly fromthe controlling display device 102 to the receiving device 106A. Forexample, this information may be associated with either pre-scanconverted ultrasound image data in polar coordinates and/or post-scanconverted ultrasound image data in cartesian coordinates. Once thisinformation is received at the receiving device 106A, it may bedisplayed (e.g., to highlight a target object in the ultrasound imagefeed 615). For example, such feature may be desirable in situationswhere a certain structure within the ultrasound image feed 615 isdesired to be highlighted or annotated for viewing at the receivingdevice 106A. In various embodiments, the highlighting or annotationinformation may be transmitted from the display device 102 to thereceiving device 106A using the same mechanisms described above for themarking signal.

Referring to FIG. 11, shown there generally as 1100 is a diagram with anultrasound imaging machine 104 having a first link-layer connection forreceiving commands that control an ultrasound image feed, and a secondlink-layer connection with a receiving device 106B having a port 168connected to a simple display, according to at least one embodiment ofthe present disclosure. The diagram of FIG. 11 is similar to that shownin FIG. 10, except that the receiving device 106A is not shown, and thedongle receiving device 106B is connected to a simple display 1102instead of an image printer 1050.

A simple display may be any display without the ability to easily loadand/or execute software that performs the acts described herein as beingperformed by a receiving device 106. For example, a simple display maybe a traditional analog television that takes analog audio/video inputs.In this case, the port 168 on the dongle 106B may provide correspondinganalog audio/video outputs so that it can be connected to the display.In another example, the display 1102 may be a more modern digitaltelevision without any “smart” capabilities. Such a display may have anHDMI input, and be connected to an embodiment of the dongle 106B with anHDMI port 168. A further example of a simple display 1102 may be atelevision pre-loaded with applications that allow it to accessmultimedia content from the Internet, but that does not have anystraightforward, user-accessible way to load software that can executeacts performed by the receiving device 106 as described herein.

These types of simple displays 1102 may be commonplace in many hospitalsand clinics. Configuring a dongle 106B to be able to connect to thesedisplays 1102 to display an ultrasound image feed may be desirable toallow a larger audience to see the ultrasound image feed being generatedat the ultrasound imaging machine 104.

As shown in FIG. 11, there is a controlling viewing device 102 with aprimary connection 108A to ultrasound imaging machine 104. FIG. 11 alsoshows the ultrasound image feed 615 being controlled by controllingdevice 102, the imaging depth 1004 and the identifier 1002 for theultrasound imaging machine 104. The ultrasound imaging machine 104 mayform a secondary connection 108B′ with the dongle 106B which can beconnected via port 168 to the simple display 1102. In operation, theultrasound image feed 615 can also be shown on the simple display 1102.In the illustrated example, the identifier 1002 for the ultrasoundimaging machine 104 and the imaging depth 1004 may also be shown on thesimple display 1102. In an example embodiment, scan conversion may takeplace at the receiving device 106B so as to convert the ultrasound imagefeed to be in a format suitable for viewing on the simple display 1102(which may have a different resolution and/or aspect ratio compared tothe controlling display device 102).

While a number of exemplary aspects and embodiments have been discussedabove, those of skill in the art will recognize that may be certainmodifications, permutations, additions and sub-combinations thereof.While the above description contains many details of exampleembodiments, these should not be construed as essential limitations onthe scope of any embodiment. Many other ramifications and variations arepossible within the teachings of the various embodiments.

Interpretation of Terms

Unless the context clearly requires otherwise, throughout thedescription and the claims:

-   -   “comprise”, “comprising”, and the like are to be construed in an        inclusive sense, as opposed to an exclusive or exhaustive sense;        that is to say, in the sense of “including, but not limited to”;    -   “connected”, “coupled”, or any variant thereof, means any        connection or coupling, either direct or indirect, between two        or more elements; the coupling or connection between the        elements can be physical, logical, or a combination thereof;    -   “herein”, “above”, “below”, and words of similar import, when        used to describe this specification, shall refer to this        specification as a whole, and not to any particular portions of        this specification;    -   “or”, in reference to a list of two or more items, covers all of        the following interpretations of the word: any of the items in        the list, all of the items in the list, and any combination of        the items in the list;    -   the singular forms “a”, “an”, and “the” also include the meaning        of any appropriate plural forms.    -   Unless the context clearly requires otherwise, throughout the        description and the claim:

Words that indicate directions such as “vertical”, “transverse”,“horizontal”, “upward”, “downward”, “forward”, “backward”, “inward”,“outward”, “vertical”, “transverse”, “left”, “right”, “front”, “back”,“top”, “bottom”, “below”, “above”, “under”, and the like, used in thisdescription and any accompanying claims (where present), depend on thespecific orientation of the apparatus described and illustrated. Thesubject matter described herein may assume various alternativeorientations. Accordingly, these directional terms are not strictlydefined and should not be interpreted narrowly.

Embodiments of the invention may be implemented using specificallydesigned hardware, configurable hardware, programmable data processorsconfigured by the provision of software (which may optionally comprise“firmware”) capable of executing on the data processors, special purposecomputers or data processors that are specifically programmed,configured, or constructed to perform one or more steps in a method asexplained in detail herein and/or combinations of two or more of these.Examples of specifically designed hardware are: logic circuits,application-specific integrated circuits (“ASICs”), large scaleintegrated circuits (“LSIs”), very large scale integrated circuits(“VLSIs”), and the like. Examples of configurable hardware are: one ormore programmable logic devices such as programmable array logic(“PALs”), programmable logic arrays (“PLAs”), and field programmablegate arrays (“FPGAs”). Examples of programmable data processors are:microprocessors, digital signal processors (“DSPs”), embeddedprocessors, graphics processors, math co-processors, general purposecomputers, server computers, cloud computers, mainframe computers,computer workstations, and the like. For example, one or more dataprocessors in a control circuit for a device may implement methods asdescribed herein by executing software instructions in a program memoryaccessible to the processors.

For example, while processes or blocks are presented in a given orderherein, alternative examples may perform routines having steps, oremploy systems having blocks, in a different order, and some processesor blocks may be deleted, moved, added, subdivided, combined, and/ormodified to provide alternative or subcombinations. Each of theseprocesses or blocks may be implemented in a variety of different ways.Also, while processes or blocks are at times shown as being performed inseries, these processes or blocks may instead be performed in parallel,or may be performed at different times.

The invention may also be provided in the form of a program product. Theprogram product may comprise any non-transitory medium which carries aset of computer-readable instructions which, when executed by a dataprocessor (e.g., in a controller and/or ultrasound processor in anultrasound machine), cause the data processor to execute a method of theinvention. Program products according to the invention may be in any ofa wide variety of forms. The program product may comprise, for example,non-transitory media such as magnetic data storage media includingfloppy diskettes, hard disk drives, optical data storage media includingCD ROMs, DVDs, electronic data storage media including ROMs, flash RAM,EPROMs, hardwired or preprogrammed chips (e.g., EEPROM semiconductorchips), nanotechnology memory, or the like. The computer-readablesignals on the program product may optionally be compressed orencrypted.

Where a component (e.g. a software module, processor, assembly, device,circuit, etc.) is referred to above, unless otherwise indicated,reference to that component (including a reference to a “means”) shouldbe interpreted as including as equivalents of that component anycomponent which performs the function of the described component (i.e.,that is functionally equivalent), including components which are notstructurally equivalent to the disclosed structure which performs thefunction in the illustrated exemplary embodiments of the invention.

Specific examples of systems, methods and apparatus have been describedherein for purposes of illustration. These are only examples. Thetechnology provided herein can be applied to systems other than theexample systems described above. Many alterations, modifications,additions, omissions, and permutations are possible within the practiceof this invention. This invention includes variations on describedembodiments that would be apparent to the skilled addressee, includingvariations obtained by: replacing features, elements and/or acts withequivalent features, elements and/or acts; mixing and matching offeatures, elements and/or acts from different embodiments; combiningfeatures, elements and/or acts from embodiments as described herein withfeatures, elements and/or acts of other technology; and/or omittingcombining features, elements and/or acts from described embodiments.

It is therefore intended that the following appended claims and claimshereafter introduced are interpreted to include all such modifications,permutations, additions, omissions, and sub-combinations as mayreasonably be inferred. The scope of the claims should not be limited bythe preferred embodiments set forth in the examples, but should be giventhe broadest interpretation consistent with the description as a whole.

What is claimed is:
 1. A dongle having a port for connecting an imageoutput device, the dongle comprising a processor for executing softwareinstructions that cause the processor to: connect to an ultrasoundmachine, the ultrasound machine being connected to a multi-use displaydevice that transmits commands to the ultrasound machine; receive anultrasound image feed generated at the ultrasound machine, theultrasound image feed being based on commands from the multi-use displaydevice; and when the image output device is connected to the port,output one or more images from the ultrasound image feed to the imageoutput device.
 2. The dongle of claim 1, wherein prior to outputting theone or more images from the ultrasound image feed to the image outputdevice, the processor is further configured to: receive a signal markingthe one or more images from the ultrasound image feed to be outputted tothe image output device; and based on the signal, marking the one ormore images to be outputted to the image output device.
 3. The dongle ofclaim 2, wherein the commands transmitted from the multi-use displaydevice to the ultrasound machine comprise the signal marking the one ormore images from the ultrasound image feed to be outputted to the imageoutput device, and the signal is transmitted from the ultrasound imagingmachine to the dongle.
 4. The dongle of claim 2, wherein the signal istransmitted from the multi-use display device to the dongle.
 5. Thedongle of claim 2, wherein the signal marking the one or more images isprovided as a field in the metadata of each frame of the ultrasoundimage feed.
 6. The dongle of claim 2, wherein each frame of theultrasound image feed is provided with a frame number, and the signalmarking the one or images indicates the frame number(s) of the one ormore images to be provided to the image output device.
 7. The dongle ofclaim 2, wherein the signal marking the one or more images is providedas an interrupt signal, and when the dongle receives the signal, theprocessor is further configured to mark the current image beingprocessed by the dongle for outputting to the image output device. 8.The dongle of claim 1, wherein the image output device comprises anultrasound image printer, and the outputted one or more images are sentto the ultrasound image printer for printing.
 9. The dongle of claim 1,wherein the ultrasound image feed is provided in a pre-scan convertedformat, and the processor is further configured to perform scanconversion on the one or more images prior to outputting the one or moreimages to the image output device.
 10. The dongle of claim 9, whereinthe scan conversion is for adapting the one or more images to a displayformat of the image output device.
 11. A method of providing anultrasound image to an image output device, the method comprising:providing a dongle having a port for connecting to the image outputdevice; the dongle connecting to an ultrasound machine, the ultrasoundmachine being connected to a multi-use display device that transmitscommands to the ultrasound machine; the dongle receiving an ultrasoundimage feed generated at the ultrasound machine, the ultrasound imagefeed being based on commands from the multi-use display device; and whenthe image output device is connected to the port, the dongle outputtingone or more images from the ultrasound image feed to the image outputdevice.
 12. The method of claim 11, wherein prior to outputting the oneor more images from the ultrasound image feed to the image outputdevice, the method further comprises: the dongle receiving a signalmarking the one or more images from the ultrasound image feed to beoutputted to the image output device; and based on the signal, thedongle marking the one or more images to be outputted to the imageoutput device.
 13. The method of claim 12, wherein the commandstransmitted from the multi-use display device to the ultrasound machinecomprise the signal marking the one or more images from the ultrasoundimage feed to be outputted to the image output device, and the signal istransmitted from the ultrasound imaging machine to the dongle.
 14. Themethod of claim 12, wherein the signal is transmitted from the multi-usedisplay device to the dongle.
 15. The method of claim 12, wherein thesignal marking the one or more images is provided as a field in themetadata of each frame of the ultrasound image feed.
 16. The method ofclaim 12, wherein each frame of the ultrasound image feed is providedwith a frame number, and the signal marking the one or images indicatesthe frame number(s) of the one or more images to be provided to theimage output device.
 17. The method of claim 12, wherein the signalmarking the one or more images is provided as an interrupt signal, andwhen the dongle receives the signal, the processor is further configuredto mark the current image being processed by the dongle for outputtingto the image output device.
 18. The method of claim 11, wherein theimage output device comprises an ultrasound image printer, and theoutputted one or more images are sent to the ultrasound image printerfor printing.
 19. The method of claim 11, wherein the ultrasound imagefeed is provided in a pre-scan converted format, and the processor isfurther configured to perform scan conversion on the one or more imagesprior to outputting the one or more images to the image output device.20. The method of claim 19, wherein the scan conversion is for adaptingthe one or more images to a display format of the image output device.